The Commelina Yellow Mottle Virus Promoter Is a Strong Promoter in Vascular Tissue of Transgenic Gossypium hirsutum Plants

Explants of cotton (Gossypium hirsutum L. cv. Jingmian 7) were transformed with Agrobacterium tumefaciens (Smith et Townsend ) Conn LBA4404 harboring an expression cassette composed of CoYMV (Commelina Yellow Mottle Virus) promoter-gus-nos terminator on the plant expression vector pBcopd2. Transgenic plants were regenerated and selected on a medium containing kanamycin. GUS (β-glucuronidase) activity assays and Southern blot analysis confirmed that the chimerical gus gene was integrated into and expressed in the regenerated cotton plants. Plant expression vector pBI121 was also transferred into the same cotton variety and the regenerated transgenic plants were used as a positive control in GUS activity analysis. Evidences from histochemical analysis of GUS activity demonstrated that under the control of a 597 bp CoYMV promoter the gus gene was highly expressed in the vascular tissues of leaves, petioles, stems, roots, hypocotyls, bracteal leaves and most of the flower parts while GUS activity could not be detected in stigma, anther sac and developing cotton fibers of the transgenic cotton plants. GUS specific activity in various organs and tissues from transgenic cotton lines was determined and the results indicated that the CoYMV promoter-gus activities were at the same level or higher than that of CaMV 35S promoter-gus in leaf veins and roots where the vascular tissues occupy a relatively larger part of the organs, but in other organs like leaves, cotyledons and hypocotyls where the vascular tissues occupy a smaller part of the organs the CoYMV promoter-gus activity was only 1/3-1/5 of the CaMV 35S promoter-gus activity. The GUS activity ratio between veins and leaves was averaged 0.5 for 35S-GUS plants and about 2.0 for CoYMV promoter-gus transgenic plants. These results further demonstrated the vascular specific property of the promoter in transgenic cotton plants. An increasing trend of GUS activity in leaf vascular tissues of transgenic cotton plants developing from young to older was observed.     

Stability of β-glucuronidase gene expression in transgenic Tricyrtis hirta plants after two years of cultivation

Transgenic plants of Tricyrtis hirta carrying the intron-containing β-glucuronidase (GUS) gene under the control of the CaMV35S promoter have been cultivated for two years. Four independent transgenic plants produced flowers 1–2 years after acclimatization, and all of them contained one copy of the transgene as indicated by inverse polymerase chain reaction (PCR) analysis. All the four transgenic plants showed stable expression of the gus gene in leaves, stems, roots, tepals, stamens and pistils as indicated by histochemical and fluorometric GUS assays, although differences in the GUS activity were observed among different organs of each transgenic plant. No apparent gus gene silencing was observed in transgenic T. hirta plants even after two years of cultivation.     

Isolation and characterization of a novel plant promoter that directs strong constitutive expression of transgenes in plants

A novel, constitutively expressed gene, designated MtHP, was isolated from the model legume species Medicago truncatula. Sequence analysis indicates that MtHP most likely belongs to the PR10 multi-gene family. The MtHP promoter was fused to a -glucuronidase gene to characterize its expression in different plant species. Transient assay by microprojectile bombardment and hairy root transformation by Agrobacterium rhizogenes revealed GUS expression in leaf, stem, radicle and root in M. truncatula. Detailed analysis in transgenic Arabidopsis plants demonstrated that the promoter could direct transgene expression in different tissues and organs at various developmental stages; its expression pattern was similar to that of CaMV35S promoter, and the level of expression was higher than the reporter gene driven by CaMV35S promoter. Deletion analysis revealed that even a 107 bp fragment of the promoter could still lead to a moderate level of expression. The promoter was further characterized in white clover (Trifolium repens), a widely grown forage legume species. Strong constitutive expression was observed in transgenic white clover plants. Compared with CaMV35S promoter, the level of GUS activity in transgenic white clover was higher when the transgene was driven by MtHP promoter. Thus, the promoter provides a useful alternative to the CaMV35S promoter in plant transformation for high levels of constitutive expression.     

A promoter from sugarcane bacilliform badnavirus drives transgene expression in banana and other monocot and dicot plants

A 1369 bp DNA fragment (Sc) was isolated from a full-length clone of sugarcane bacilliform badnavirus (ScBV) and was shown to have promoter activity in transient expression assays using monocot (banana, maize, millet and sorghum) and dicot plant species (tobacco, sunflower, canola and Nicotiana benthamiana). This promoter was also tested for stable expression in transgenic banana and tobacco plants. These experiments showed that this promoter could drive high-level expression of the -glucuronidase (GUS) reporter gene in most plant cells. The expression level was comparable to the maize ubiquitin promoter in standardised transient assays in maize. In transgenic banana plants the expression levels were variable for different transgenic lines but was generally comparable with the activities of both the maize ubiquitin promoter and the enhanced cauliflower mosaic virus (CaMV) 35S promoter. The Sc promoter appears to express in a near-constitutive manner in transgenic banana and tobacco plants. The promoter from sugarcane bacilliform virus represents a useful tool for the high-level expression of foreign genes in both monocot and dicot transgenic plants that could be used similarly to the CaMV 35S or maize polyubiquitin promoter.     

Induced expression of a chimeric gene construct in transgenic lettuce plants using tobacco pathogenesis-related protein gene promoter region

The expression of a stress- and salicylic acidinducible protein gene from tobacco, PR1a protein gene, was determined after its Introduction to lettuce (Lactuca sativa L.) plants. The 5 flanking 2.4 Kb fragment from PR1a gene was joined to the bacterial -glucuronidase (GUS) gene (PR-GUS) and introduced into lettuce cotyledons by Agrobacterium-mediated gene transfer using a binary vector containing a kanamycin-resistance gene as a selectable marker. As a control with constitutive expression, the chimeric gene consisting of CaMV 35S RNA promoter and GUS gene (35S-GUS) was used. An improved method for shoot formation directly from lettuce cotyledons was used effectively for transformation, shortening the time for regeneration. In 70% or more of kanamycin-resistant regenerated lettuce plants, into which PR-GUS or 35S-GUS was introduced, high GUS activity and integration of the chimeric gene into the lettuce genome were detected. By treatment with salicylic acid, GUS activity increased 3- to 50-fold in PR-GUS transformants, however, no increase was detected in 35S-GUS plants. These results showed that the promoter of the stress-inducible tobacco PR1a protein gene was introduced into lettuce plants, and the introduced chimeric gene was expressed normally under the regulated control of the PRla promoter.Abbreviations BA N6-benzyladenine - GUS -glucuronidase - NAA -naphthaleneacetic acid - Km kanamycin - Km^s kanamycin resistant - Km⁰ kanamycin sensitive - NPT- II neomycin phosphotransferase II - PR pathogenesis-related - SA salicylic acid - MS Murashige and Skoog medium - NOS nopaline synthase     

Promoters for pregenomic RNA of banana streak badnavirus are active for transgene expression in monocot and dicot plants

Two putative promoters from Australian banana streak badnavirus (BSV) isolates were analysed for activity in different plant species. In transient expression systems the My (2105 bp) and Cv (1322 bp) fragments were both shown to have promoter activity in a wide range of plant species including monocots (maize, barley, banana, millet, wheat, sorghum), dicots (tobacco, canola, sunflower, Nicotiana benthamiana, tipu tree), gymnosperm (Pinus radiata) and fern (Nephrolepis cordifolia). Evaluation of the My and Cv promoters in transgenic sugarcane, banana and tobacco plants demonstrated that these promoters could drive high-level expression of either the green fluorescent protein (GFP) or the -glucuronidase (GUS) reporter gene (uidA) in vegetative plant cells. In transgenic sugarcane plants harbouring the Cv promoter, GFP expression levels were comparable or higher (up to 1.06% of total soluble leaf protein as GFP) than those of plants containing the maize ubiquitin promoter (up to 0.34% of total soluble leaf protein). GUS activities in transgenic in vitro-grown banana plants containing the My promoter were up to seven-fold stronger in leaf tissue and up to four-fold stronger in root and corm tissue than in plants harbouring the maize ubiquitin promoter. The Cv promoter showed activities that were similar to the maize ubiquitin promoter in in vitro-grown banana plants, but was significantly reduced in larger glasshouse-grown plants. In transgenic in vitro-grown tobacco plants, the My promoter reached activities close to those of the 35S promoter of cauliflower mosaic virus (CaMV), while the Cv promoter was about half as active as the CaMV 35S promoter. The BSV promoters for pregenomic RNA represent useful tools for the high-level expression of foreign genes in transgenic monocots.     

Spacer length-dependent protection of specific activity of pollen and/or embryo promoters from influence of CaMV 35S promoter/enhancer in transgenic plants

The influence of the CaMV 35S promoter/enhancer on expression profiles of four Arabidopsis thaliana pollen- and/or embryo-specific promoters, APRS, ESL, MXL, and DLL, was tested in transgenic tobacco plants. Individual promoters were fused to the gus reporter gene and cloned in head-to-head orientation with the CaMV 35S:hpt expression unit within the same T-DNA. With the exception of the TATA-less promoter DLL, all other combinations generated interactions between the promoter under investigation and 35S promoter/enhancer resulting in ectopic β-glucuronidase (GUS) expression in vegetative organs and tissues, the most susceptible being the stem, followed by callus, leaf, and root. To eliminate this crosstalk, DNA spacers of length 1, 2 and 5 kb were cloned between the interacting sequences. Ectopic GUS staining was dependent on the affected promoter as well as the distance between the 5′-end of the CaMV 35S promoter and the reporter gene translation start site. When this distance was less than 1 kb strong ectopic GUS staining was observed in all vegetative tissues, similar to the CaMV35S:gus expression profile in transgenic tobacco plants. Insertion of spacer DNA sequences of increasing length resulted in gradual reduction of ectopic GUS staining in tested plants. Of the tissues and organs related to plant reproduction, only anthers and seed coats in the early stages of seed development showed ectopic GUS staining. Developing pollen and embryos showed a pattern of GUS activity consistent with the predicted role of a developmental stage-specific promoter in transgenic tobacco plants.     

Inheritance of gusA and neo genes in transgenic rice

Inheritance of foreign genes neo and gusA in rice (Oryza sativa L. cv. IR54 and Radon) has been investigated in three different primary (T₀) transformants and their progeny plants. T₀ plants were obtained by co-transforming protoplasts from two different rice suspension cultures with the neomycin phosphotransferase II gene [neo or aph (3) II] and the -glucuronidase gene (uidA or gusA) residing on separate chimeric plasmid constructs. The suspension cultures were derived from callus of immature embryos of indica variety IR54 and japonica variety Radon. One transgenic line of Radon (AR2) contained neo driven by the CaMV 35S promoter and gusA driven by the rice actin promoter. A second Radon line (R3) contained neo driven by the CaMV 35S promoter and gusA driven by a promoter of the rice tungro bacilliform virus. The third transgenic line, IR54-1, contained neo driven by the CaMV 35S promoter and gusA driven by the CaMV 35S.Inheritance of the transgenes in progeny of the transgenic rice was investigated by Southern blot analysis and enzyme assays. Southern blot analysis of genomic DNA showed that, regardless of copy numbers of the transgenes in the plant genome and the fact that the two transgenes resided on two different plasmids before transformation, the introduced gusA and neo genes were stably transmitted from one generation to another and co-inherited together in transgenic rice progeny plants derived from self-pollination. Analysis of GUS and NPT II activities in T₁ to T₂ plants provided evidence that inheritance of the gusA and neo genes was in a Mendelian fashion in one plant line (AR2), and in an irregular fashion in the two other plant lines (R3 and IR54-1). Homozygous progeny plants expressing the gusA and neo genes were obtained in the T₂ generation of AR2, but the homozygous state was not found in the other two lines of transgenic rice.     

Comparing constitutive promoters using CAT activity in transgenic tobacco plants

The effectiveness of different promoters for use in transgenic tobacco was compared using a reporter gene expressing chloramphenicol acetyl transferase (CAT). Plasmids with CAT gene controlled by cauliflower mosaic virus 35S (CaMV 35S), rice actin1 (Ract1) and tobacco polyubiquitin (Tubi.u4) promoters were delivered into tobacco plants by Agrobacterium-mediated transformation. The Ract1 promoter, previously shown to be a strong promoter in rice and other monocots, failed to promote strong expression in tobacco. CAT expression was greatest from the vector carrying Tubi.u4 with a 5'UTR and leader intron without a ubiquitin monomer. In transgenic plants harboring the Tubi.u4 promoter, CAT expression was approximately twice that of the CaMV 35S promoter. Our results suggest that foreign genes under the control of a ubiquitin promoter devoid of monomer will be useful for high-level gene expression in tobacco.     

Optimised DNA delivery into Coffea arabica suspension culture cells by particle bombardment

An optimised bombardment protocol to introduce DNA into Coffea arabica suspension culture cells was developed. Osmotic preconditioning of cells and physical bombardment parameters including Helium pressure, gap and target distances affecting DNA delivery were evaluated by monitoring transient expression of the uidA gene driven by the CaMV35S promoter. The highest transient GUS expression was obtained when cells were subjected to a 0.5 M mannitol–sorbitol pre-treatment 4 h prior to bombardment and a Helium pressure of 1550 psi, a 9-mm gap distance and 12 cm target distance as physical bombardment parameters. The optimised protocol was tested with two coffee promoters: -tubulin and arabicin, which presented similar activity to the CaMV35S promoter in suspension culture cells by fluorometric GUS assays. GUS expression was reduced in bombarded tissue culture leaves, and only the CaMV35S and arabicin promoters showed histochemical activity in coffee endosperms. This is the first report of optimization of particle bombardment on coffee suspension culture cells, equivalent CaMV35S activity for a coffee promoter and transient -glucoronidase expression in coffee endo-sperms.